Devices and Methods for a Pyrolysis and Gasification System for Biomass Feedstock

ABSTRACT

A pyrolysis and gasification system produce a synthesis gas and bio-char from a biomass feedstock. The system includes a feed hopper that has a flow measurement device. The system also includes a reactor that is operable in a gasification mode or a pyrolysis mode. The reactor is configured to receive the biomass feedstock from the feed hopper. The reactor is operable to provide heat to the biomass feedstock from the feed hopper to produce the synthesis gas and bio-char. The system also includes a cyclone assembly. The produced synthesis gas including the bio-char is fed to the cyclone assembly. The cyclone assembly removes a portion of the bio-char from the synthesis gas.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.16/502,941 filed on Jul. 3, 2019, which is a continuation of U.S.application Ser. No. 13/577,248 filed Oct. 23, 2012, which was filedunder 35 U.S.C. 371 based upon International Application Serial No.PCT/US2011/023933 filed Feb. 7, 2011 which claims priority to U.S.Provisional Application Ser. No. 61/302,001 filed Feb. 5, 2010, thedisclosures of which are incorporated by reference herein in theirentirety.

BACKGROUND OF THE INVENTION Field of the Invention

This invention relates to the field of biomass conversion and morespecifically to the field of pyrolysis and gasification of biomassfeedstock.

Background of the Invention

Methods for using energy from biomass have conventionally includedcombustion of the biomass with the heat energy used to produce steam.The steam may then be used to produce electric power. Drawbacks to suchconventional methods include slagging and fouling that occur withbiomass fuels containing low eutectic point (i.e., melting point) ash.For instance, the ash melts at relatively low temperatures and sticks tosurfaces, which may impact the sustainability of the thermal conversionsystem. Developments have included using bag filters to remove char byfiltration. For such developments, the gas temperature is cooled to atemperature at which the temperature of the gas is below the temperaturethat may result in damage to the bag filter media. Drawbacks to suchdevelopments include inefficiencies with the performance of the bagfilter for removing the smaller particulates.

Consequently, there is a need for an improved system for conversion ofbiomass. Additional needs include a mobile pyrolysis and gasificationsystem for biomass feedstock.

BRIEF SUMMARY OF SOME OF THE PREFERRED EMBODIMENTS

These and other needs in the art are addressed in one embodiment by apyrolysis and gasification system for producing a synthesis gas andbio-char from a biomass feedstock. The system includes a feed hopperthat has a flow measurement device. The system also includes a reactorthat is operable in a gasification mode or a pyrolysis mode. The reactoris configured to receive the biomass feedstock from the feed hopper. Thereactor is operable to provide heat to the biomass feedstock from thefeed hopper to produce the synthesis gas and bio-char. The system alsoincludes a cyclone assembly. The produced synthesis gas having bio-charis fed to the cyclone assembly. The cyclone assembly removes bio-charfrom the synthesis gas.

These and other needs in the art are addressed in another embodiment bya method for gasification and pyrolysis of a biomass feedstock in areactor. The reactor includes bed materials. The method includesintroducing a fluidizing medium to the bed materials to fluidize the bedmaterials and to produce a fluidized condition. The method also includesheating the bed materials to a desired temperature. The heating isprovided by a heat source. The method also includes feeding the biomassfeedstock to the bed materials. A reaction produces a synthesis gas andbio-char from the biomass feedstock. In addition, the method includescontrolling the temperature of the bed materials to maintain thefluidized condition in a pyrolysis mode. The method further includesremoving the bio-char from the reactor.

The foregoing has outlined rather broadly the features and technicaladvantages of the present invention in order that the detaileddescription of the invention that follows may be better understood.Additional features and advantages of the invention will be describedhereinafter that form the subject of the claims of the invention. Itshould be appreciated by those skilled in the art that the conceptionand the specific embodiments disclosed may be readily utilized as abasis for modifying or designing other embodiments for carrying out thesame purposes of the present invention. It should also be realized bythose skilled in the art that such equivalent embodiments do not departfrom the spirit and scope of the invention as set forth in the appendedclaims.

BRIEF DESCRIPTION OF THE DRAWINGS

For a detailed description of the preferred embodiments of theinvention, reference will now be made to the accompanying drawings inwhich:

FIG. 1 illustrates a side perspective view of an embodiment of apyrolysis and gasification system;

FIG. 2 illustrates a side view of the embodiment of the pyrolysis andgasification system illustrated in FIG. 1;

FIG. 3 illustrates a side view of an embodiment of a pyrolysis andgasification system having a pressure swing absorption system; and

FIG. 4 illustrates a side view of an embodiment of a pyrolysis andgasification system having an auger and the reactor bed.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 illustrates a side perspective view of an embodiment of pyrolysisand gasification system 5 that includes feed hopper 10, reactor 15,reactor bed 20, cyclone assembly 25, and char collector 30. FIG. 2illustrates a side view of the embodiment of pyrolysis and gasificationsystem 5 illustrated in FIG. 1. It is to be understood that reactor bed20 is disposed within reactor 15. In an embodiment, pyrolysis andgasification system 5 produces synthesis gas (i.e., syngas), bio-char(i.e., char) and bio-oil from a biomass feedstock. Pyrolysis andgasification system 5 also produces syngas 70. The biomass feedstock mayinclude any biomass. For instance, without limitation, examples of thebiomass feedstock include cotton gin trash (for instance, pulverizedcotton gin trash or raw cotton gin trash), switch grass, sorghum,sludge, straw, rye, wood chips, poultry litter, dairy manure, and thelike. The reactor 15 is operable in a gasification mode or a pyrolysismode. It is to be understood that gasification mode refers to the use ofan oxidant for conversion that is below stoichiometric limits. It is tobe further understood that pyrolysis mode refers to incomplete absenceof oxygen during conversion.

As shown in FIGS. 1 and 2, feed hopper 10 has a sufficient height anddepth to achieve a desired continuous feed of biomass feedstock toreactor 15. In an embodiment, the biomass feedstock is fed to the topportion 105 of feed hopper 10. In some embodiments, feed hopper 10includes a flow measurement device 100. Flow measurement device 100 maybe any device suitable for measuring the feed of biomass feedstock toreactor 15. Feed hopper 10 also includes reactor feed 35. Reactor feed35 is a connection between feed hopper 10 and reactor 15 by which thebiomass feedstock is fed to reactor 15 from feed hopper 10.

As further shown in FIGS. 1 and 2, embodiments of reactor 15 includereactor bed 20 disposed within reactor 15. Reactor 15 may include anysuitable type of burner. In an embodiment, the burner is a natural gasor propane burner. Any type of combustible gas suitable for reactor 15may be used. In an embodiment, the gas may include nitrogen, helium,argon, or any combinations thereof. In embodiments, the gas is nitrogen.Embodiments of pyrolysis and gasification system 5 also include afluidizing medium input (not illustrated) and an air distribution system(not illustrated). The fluidizing medium input provides a fluidizingmedium to the air distribution system. Any fluidizing medium suitable tofluidize reactor bed 20 may be used. In an embodiment, the fluidizingmedium is air, an inert gas, or any combinations thereof. In anembodiment, the fluidizing medium is air. The air distribution systemprovides the fluidizing medium to the reactor bed 20. In embodiment, theprovided fluidizing medium fluidizes the reactor bed 20. In embodiments,the air distribution system is submerged in the bed materials of reactorbed 20. Without limitation, the air distribution system may include anymethod suitable to fluidize reactor bed 20. For instance, inembodiments, the air distribution system includes a plate with orificesor bubble caps. In embodiments, the angle of repose of the bed materialsis noted, and the height of the bubble caps is designed to be greaterthan the angle of repose of the bed materials. Any bed materialssuitable for a fluidized bed in a reactor may be used for reactor bed20. In embodiments, the bed materials are minerals with a sand-likeconsistency. In an embodiment, examples of suitable bed materialsinclude alumina, refractory, and metal-based refractory. Withoutlimitation, a commercial example of the bed materials is Mulcoa Mulgrainprovided by C-E Minerals. In an embodiment, the particle size of the bedmaterials is selected for a desired air flow. In some embodiments, thebed materials are not provided in different sizes but may only beavailable with all sizes combined. In such embodiments, the bedmaterials of the desired size are separated by sieve shaking. In someembodiments, the size of the bed materials is selected to achieve adesired air flow rate. Without limitation, in an embodiment, changingthe size of the bed material during operation allows pyrolysis andgasification system 5 to operate at higher throughput without increasingthe diameter of the fluidized reactor bed 20.

Reactor 15 may have any suitable configuration for pyrolysis andgasification of the biomass feedstock. In embodiments as shown in FIGS.1 and 2, reactor 15 has a narrower bottom portion 110 with an upperportion 115 that increases in diameter over that of bottom portion 110.Without limitation, such increase in diameter reduces the velocity ofthe air flow in the upper portion 110. Further, without limitation, suchreduction in velocity facilitates the heavier bed materials remaining inreactor 15 and the lighter produced char exiting reactor 15. It is to beunderstood that reactor 15 is not limited to such a configuration but inalternative embodiments (not illustrated) may have any suitableconfiguration for pyrolysis and gasification of the biomass feedstock.

As further shown in FIGS. 1 and 2, embodiments of pyrolysis andgasification system 5 include cyclone assembly 25. Cyclone assembly 25removes char from the produced syngas exiting reactor 15. Cycloneassembly 25 may have any suitable number of cyclones. In embodiments asshown, cyclone assembly 25 has two cyclones, first cyclone 40 and secondcyclone 45. Without limitation, two cyclones 40, 45 maximize removal ofthe solid by-product (i.e., char) from the syngas. In an embodiment,first cyclone 40 is a low energy cyclone, and second cyclone 45 is ahigh efficiency cyclone. It is to be understood that a low energycyclone removes larger particles that would impact the performance ofthe high efficiency cyclones on the second stage. It is also to beunderstood that a high efficiency cyclone removes the finer charparticles to limit particulate emissions. Without limitation, the charmust be removed first prior to the use of syngas in order to preventslagging and fouling in downstream conveying surfaces. The charseparated from the syngas is fed to char collector 30. The syngas 70separated from the char exits cyclone assembly 25.

FIG. 3 illustrates an embodiment of pyrolysis and gasification system 5in which syngas 70 is fed to pressure swing absorption system 50.Pressure swing absorption system 50 removes desired contaminants fromthe syngas 70 and provides reduced contaminant syngas 75. The desiredcontaminants include carbon monoxide, methane, and hydrogen. In anembodiment as shown, pressure swing absorption system 50 has twoabsorbers, first absorber 55 and second absorber 60. First absorber 55and second absorber 60 each have an activated carbon section 120 and amolecular sieve section 125. In embodiments, the syngas 70 passesthrough activated carbon section 120 and then passes through molecularsieve section 125 before exiting first absorber 55 or second absorber 60as reduced contaminant syngas 75. In alternative embodiments (notillustrated), the syngas 70 passes through molecular sieve section 125and then passes through activated carbon section 120 before exitingfirst absorber 55 or second absorber 60 as reduced contaminant syngas75. The activated carbon may include any suitable source of activatedcarbon for removing desired contaminants from syngas 70. Withoutlimitation, an example of a suitable activated carbon source is coconutshell. The molecular sieve may include any suitable molecular sieve forremoving desired contaminants from syngas 70 but allowing syngas 70 topass therethrough. In embodiments, the molecular sieve has a pore sizebetween about 9 Angstroms and about 10 Angstroms. In an embodiment, themolecular sieve is a 13(A) molecular sieve. Without limitation, themolecular sieve has a sufficient pore size selected to absorb hydrogen.Any materials suitable for absorbing contaminants may be used for themolecular sieve. In an embodiment, the molecule sieve is impregnatedwith cuprous oxides. In embodiments, the molecular sieve materials arecalcined. Without limitation, calcined molecular sieve materials providefor the contaminants to be adsorbed on the outside of the molecularsieve materials. In some embodiments, the hydrogen and methane purgedfrom the absorbers are separated. It is to be understood that suchhydrogen and methane have value as products.

In an embodiment of operation of the embodiments illustrated in FIGS.1-3, operation of pyrolysis and gasification system 5 includes preparingthe bed material of reactor bed 20. In some embodiments, preparing thebed materials includes separating the desired size of bed materials fromthe bed materials of different sizes. The desired bed materials are thenplaced in reactor 15 to provide reactor bed 20. The fluidized mediuminput then provides pressure to the bed materials to fluidize the bed.In an embodiment, the fluidized medium is air, which when added toreactor bed 20 by the air distribution system provides the pressure. Inembodiments, a minimum air flow is desired to fluidize the reactor bed20. Without limitation, the minimum air flow prevents the reactor bed 20from becoming a solid mass after the biomass feedstock packs between thebed material particles. In an embodiment, the minimum air flow isdependent upon the size of bed materials used.

With reactor bed 20 fluidized by the air from the air distributionsystem, embodiments of operation as shown in FIGS. 1-3 includeactivating the burner in reactor 15 to provide heat to the fluidizedreactor bed 20 (i.e., by the burner burning nitrogen). In an embodiment,the reactor bed 20 is heated to about 600° C. to about 800° C.,alternatively to about 800° C. to about 900° C. In embodiments, thediameter of the fluidized reactor bed 20 may be increased for higherthermal inputs. After the fluidized reactor bed 20 is heated to adesired temperature, the burner is turned off (i.e., combustion gas feedis stopped), and the biomass feedstock is fed to feed hopper 10 and fromfeed hopper 10 to reactor 15 via reactor feed 35. The heated andfluidized reactor bed 20 transfers heat to the biomass feedstock,converting a portion of the biomass feedstock to syngas. The producedsyngas flows up reactor 15 and out to cyclone assembly 25. In cycloneassembly 25, char is removed from the syngas, with the char exitingcyclone assembly 25 to char collector 30. The syngas 70 exits cycloneassembly 25.

In embodiments as further shown in FIGS. 1-3, to increase the flow ofbiomass feedstock through reactor 15, the biomass feedstock feed rateand fluidizing medium flow rate may be increased. In an embodiment, thebiomass feedstock feed rate is adjusted. In some embodiments, thebiomass feedstock is below the eutectic point. Flow measurement device100 determines the feed rate of the biomass feedstock to reactor 15. Inembodiments, the fluidizing medium (i.e., air) flow rate and the biomassfeedstock feed rate are adjusted to maintain a desired air to feedstockratio. In some embodiments, the feedstock flow rate (i.e., volume) isadjusted to keep the reaction temperature constant, which prevents thereaction from proceeding into combustion mode and maintains thegasification mode of the reactor bed 20. It is to be understood thatcombustion mode refers to use of excess air for conversion that is abovethe stoichiometric limits. In an embodiment, if an increase intemperature of reactor 15 is desired, the air feed through the airdistribution system is increased while maintaining the biomass feedstockfeed rate. If a decrease in temperature is desired, the biomassfeedstock feed rate is increased while maintaining the air feed (i.e.,maintaining fluidization conditions of reactor bed 20). In embodiments,the feed ratio is maintained between about 0.2-0.4 equivalents (i.e.,air to feedstock ratio). In an embodiment, a control system is providedfor pyrolysis and gasification system 5 that automates the process. Theautomated process may adjust parameters such as the air flow rate andbiomass feedstock feed rate based on set air to feedstock ratios.

In an embodiment of operation of the embodiments illustrated in FIG. 3,the produced syngas 70 may be fed to pressure swing absorption system 50for removal of contaminants to provide reduced contaminant syngas 75. Insome embodiments, reduced contaminant syngas 75 has about 0.1 wt. % orless hydrogen than syngas 70. In embodiments, syngas 70 is fed throughfirst absorber 55 or second absorber 60 for absorption of contaminantswith the non-operating first absorber 55 or second absorber 60 beingpurged of contaminants. When syngas 70 is fed to first absorber 55 orsecond absorber 60 for absorption of contaminants, the operatingabsorber (i.e., first absorber 55 or second absorber 60) is operated atany conditions suitable for absorption of contaminants. In anembodiment, the operating conditions include a pressure between about310 kPa and about 710 kPa. In embodiments, the operating conditionsinclude temperatures between about 150° C. and about 200° C. When theoperating absorber is receiving the syngas 70 for absorption ofcontaminants, the other absorber may be purged of contaminants. Purgingmay be carried out at any conditions suitable for purging ofcontaminants. In an embodiment, purging conditions include a pressurebetween about atmosphere and about 310 kPa, alternatively between about310 kPa and about 710 kPa. In embodiments, the purging conditionsinclude temperatures between about 400° C. and about 600° C. Forinstance, in an embodiment, syngas 70 is fed to first absorber 55 andnot second absorber 60. First absorber 55 is operated at suitablecontaminant absorption conditions. First absorber 55 may operate toabsorb contaminants for any desirable time period. In an embodiment,first absorber 55 absorbs contaminants from syngas 70 for between about5 minutes and about 10 minutes. Without limitation, larger sizedabsorbers may be used for longer periods of absorption. After such adesired time period (i.e., between about 5 minutes and about 10minutes), the feed of syngas 70 to first absorber 55 is stopped, and thesyngas 70 is then fed to second absorber 60. Second absorber 60 isoperated at absorption conditions for absorption of contaminants toproduce reduced contaminant syngas 75. With no syngas 70 fed to firstabsorber 55, first absorber 55 is operated at purging conditions topurge the contaminants. After second absorber 60 has absorbedcontaminants from syngas 70 for a desired time period (i.e., betweenabout 5 minutes and about 10 minutes), syngas 70 is fed again to firstabsorber 55 for absorption with second absorber 60 being purged ofcontaminants. The purging and absorption may be switched between theabsorbers 55, 60 for any desirable number of times. The purging may beaccomplished with any suitable gas. In an embodiment, the purging gas isair. It is to be understood that pressure swing absorption system 50 isnot limited to two absorbers, but in alternative embodiments (notillustrated), pressure swing absorption system 50 has more than twoabsorbers.

In embodiments (not illustrated), syngas 70 is fed to a condenser (notillustrated) to produce bio-oil from the syngas 70. The condenser may beoperated at any suitable conditions to condense the syngas and producethe bio-oil. In an embodiment, reduced contaminant syngas 75 is fed to acondenser to produce bio-oil. In other embodiments (not illustrated),pyrolysis and gasification system 5 include reforming of the syngas 70and/or reduced contaminant syngas 75 into synthetic liquid fuel viasuitable catalytic processes.

FIG. 4 illustrates an alternative embodiment of pyrolysis andgasification system 5 in which reactor 15 includes auger 80. Auger 80 isdisposed in upper portion 115 of reactor 15. Auger 80 includes any typeof auger suitable for providing the biomass feedstock from feed hopper10 to upper portion 115. In embodiments, auger 80 includes a pipedisposed in upper portion 115 to which the auger 80 provides the biomassfeedstock. Reactor bed 20 is fluidized and heated as in the embodimentsof FIGS. 1-3. Heat produced from the heated reactor bed 20 rises upthrough reactor 15 and pyrolyzes a portion of the biomass feedstock toproduce syngas. The syngas exits reactor 15. In embodiments, the syngas(with char) as syngas feed 85 exits reactor 15 and is fed to condenser90 to produce bio-oil 95.

Without limitation, operation of pyrolysis and gasification system 5provides for sustainable thermal conversion of energy using a wide rangeof biomass feedstock containing ash with a low melting point (i.e., loweutectic point) into a low calorific value gas (i.e., syngas 70). Insome embodiments, syngas 70 and reduced contaminant syngas 75 may becombusted and used as heat in a boiler/steam turbine or directly in anengine/generator for electric power. In addition, the char may beremoved from char collector 30. In embodiments, the produced char mayhave value as activated carbon or as soil enhancement. It is to beunderstood that pyrolysis and gasification system 5 may be sized up ordown and may have any desired throughput of biomass feedstock. Forinstance, the pyrolysis and gasification system 5 may be sized up ordown with different throughputs to produce any desired amount of poweroutput. In some embodiments, pyrolysis and gasification system 5 may bescaled to allow for production of less than 1 MW of power output,alternatively from about 1 MW to about 3 MW of power output, andalternatively from about 1 MW to about 6 MW of power output. Inembodiments, such output is produced with a single diameter fluidizedbed (i.e., reactor bed 20), which in some embodiments is designed forone million Btu per square foot per hour or higher input.

In an embodiment, applications of pyrolysis and gasification system 5provide a source of electric power for operating a cotton gin with therecovery of waste heat lost by pyrolysis and gasification system 5 usedfor drying the seed cotton in the ginning process. In an embodiment,there is sufficient energy in 250 pounds of gin trash per bale tooperate the power plant and operate the gin at 50 kilowatt-hours perbale and 200,000 Btu per bale for drying with a thermal efficiency of10%. For instance, a gin processing stripped cotton with a cleaner mayaverage about 400 pounds of gin trash per bale. Stripped cotton withouta cleaner typically contains 700 to 1,000 pounds of gin trash per bale.The biomass left in the field after harvesting may exceed 2 tons peracre. In an embodiment, an electric power generation system may includepyrolysis and gasification system 5 that may be operated to produce 1,2, and 3 MW output using the low calorific value (LCV) gas (i.e., syngas70 or reduced contaminant syngas 75) used to power an engine/generator.In embodiments, 1, 2, and 3 MW power outputs may provide sufficientelectric power to operate 20, 40, and 60 bale per hour cotton gins,respectively. In embodiments, the pyrolysis and gasification system 5may be engineered to operate at 1, 2, and 3 MW by adjusting the size ofthe bed materials for reactor bed 20, the biomass feedstock feed rate,and/or the air flow rate for fluidizing the reactor bed 20 to maintain aconstant fuel-to-air ratio. The syngas 70 and/or reduced contaminantsyngas 75 produced may operate the corresponding engine/generator sizesfor power generation. In an embodiment, substantially all generatedelectric power not used by the gin may be returned to a grid as returnedpower.

In embodiments, the operating conditions of pyrolysis and gasificationsystem 5 are adjusted depending on the desired products. For instance,the operating conditions may be modified depending on whether theamounts of bio-oil, char or syngas (i.e., syngas 70 and/or reducedcontaminant syngas 75) are desired to be adjusted. It is to beunderstood that conditions vary with different biomass feedstocks. In anembodiment, the operating temperature of reactor 15 is between about400° C. and about 600° C. Without limitation, such temperature rangeincreases the amount of bio-oil produced. In embodiments, increasing thefeed rate of the biomass feedstock increases the amount of bio-fuelproduced. In some embodiments, the operating temperature of reactor 15is between about 300° C. and about 400° C. Without limitation, suchtemperature range increases the amount of char produced. In embodiments,the operating temperature is between about 700° C. and about 800° C.Without limitation, such temperature range increases the amount ofsyngas produced.

In an embodiment, reactor 15 includes insulation (not illustrated). Anysuitable insulation for a reactor may be used. In an embodiment, theinsulation is made of refractory material. In some embodiments, reactor15 includes a gap (not illustrated) between the reactor bed 20 and therefractory insulation. Without limitation, the gap allows for theremoval of excess heat from the reactor 15 to heat the incoming air forimproved efficiency. In some embodiments, the gap may allow the use ofsteam through the input air to improve the quality of syngas 70.

In an embodiment, pyrolysis and gasification system 5 may be operated ina continuous mode without the use of external power. In such anembodiment, pyrolysis and gasification system 5 may be plugged intoanother operational fluidized bed gasifier (i.e., another pyrolysis andgasification system 5) and therefore would not need any external heat.

In embodiments, pyrolysis and gasification system 5 is transportable.Pyrolysis and gasification system 5 may be transported by any suitablemeans. In an embodiment, pyrolysis and gasification system 5 is disposedupon a trailer, which is pulled by a vehicle such as a tractor trailer.

Although the present invention and its advantages have been described indetail, it should be understood that various changes, substitutions andalterations may be made herein without departing from the spirit andscope of the invention as defined by the appended claims.

What is claimed:
 1. A pyrolysis and gasification system for producing asynthesis gas and bio-char from a biomass feedstock, comprising: a feedhopper, wherein the feed hopper comprises a flow measurement device; areactor that is operable in a gasification mode or a pyrolysis mode, andwherein the reactor is configured to received the biomass feedstock fromthe feed hopper, and further wherein the reactor is operable to provideheat to the biomass feedstock from the feed hopper to produce thesynthesis gas and bio-char; the reactor including an upper portion and alower portion, a cyclone assembly, wherein the produced synthesis gascomprising bio-char is fed to the cyclone assembly, and wherein thecyclone assembly removes bio-char from the synthesis gas, and an augerdisposed in an upper portion of the reactor and adapted to conveybiomass feedstock from the feed hopper to the reactor.
 2. The pyrolysisand gasification system of claim 1, wherein the reactor comprises areactor bed, wherein the reactor bed is fluidized by a fluidizing mediuminput.
 3. The pyrolysis and gasification system of claim 1, wherein thereactor comprises an upper portion and a bottom portion, and wherein theupper portion comprises an increased diameter over a diameter of thebottom portion.
 4. The pyrolysis and gasification system of claim 1,wherein the cyclone assembly comprises a first cyclone and a secondcyclone.
 5. The pyrolysis and gasification system of claim 1, furthercomprising a pressure swing absorption system, wherein the producedsynthesis gas is fed to the pressure swing absorption system to removecontaminants from the synthesis gas.
 6. The pyrolysis and gasificationsystem of claim 5, wherein the pressure swing absorption systemcomprises a first absorber and a second absorber, wherein the secondabsorber is purged of absorbed contaminants when the first absorber isabsorbing contaminants from the synthesis gas, and wherein the firstabsorber is purged of contaminants when the second absorber is absorbingcontaminants from the synthesis gas.
 7. The pyrolysis and gasificationsystem of claim 6, wherein the first absorber and the second absorbereach comprise an activated carbon section and a molecular sieve section.8. The pyrolysis and gasification system of claim 1, further comprisinga condenser, wherein the synthesis gas is fed to the condenser toproduce bio-oil.
 9. The pyrolysis and gasification system of claim 1,wherein the bio-char from the cyclone assembly is fed to a charcollector.
 10. The pyrolysis and gasification system of claim 1, whereinoperating conditions of the reactor are adjustable to control productionof the bio-char and synthesis gas. 11-20. (canceled)